High resolution scanning electron microscopy of plasmodesmata

Symplastic transport occurs between neighbouring plant cells through functionally and structurally dynamic channels called plasmodesmata (PD). Relatively little is known about the composition of PD or the mechanisms that facilitate molecular transport into neighbouring cells. While transmission electron microscopy (TEM) provides 2-dimensional information about the structural components of PD, 3-dimensional information is difficult to extract from ultrathin sections. This study has exploited high-resolution scanning electron microscopy (HRSEM) to reveal the 3-dimensional morphology of PD in the cell walls of algae, ferns and higher plants. Varied patterns of PD were observed in the walls, ranging from uniformly distributed individual PD to discrete clusters. Occasionally the thick walls of the giant alga Chara were fractured, revealing the surface morphology of PD within. External structures such as spokes, spirals and mesh were observed surrounding the PD. Enzymatic digestions of cell wall components indicate that cellulose or pectin either compose or stabilise the extracellular spokes. Occasionally, the PD were fractured open and desmotubule-like structures and other particles were observed in their central regions. Our observations add weight to the argument that Chara PD contain desmotubules and are morphologically similar to higher plant PD.     

High resolution scanning electron microscopy of the cell

The scanning electron microscope (SEM) has become a powerful tool for ultrastructural research with improvement of the instrument's resolution and progress in specimen preparation techniques. With regard to resolution, it has been improved step-by-step in this decade and, in 1985, an ultra-high resolution SEM (UHS-T1) was developed, with a resolution of 0.5 nm. Concerning specimen preparation, the osmium-DMSO-osmium method, which is effective for revealing intracellular structures, has come to be widely used. Techniques for observing smaller objects, such as bacteriophages, viruses, and biological macromolecules, have also been devised in recent years. As a result of these preparation techniques and the availability of the ultra-high resolution SEM, the application of SEM in biology is expanding rapidly. In this paper, an outline of the ultra-high resolution SEM, techniques for specimen preparation, findings of some biological materials by these techniques, and guidelines to making the specimens, are described.     

High resolution scanning electron microscopy of plant chromosomes

A preparation technique for high resolution field emission scanning electron microscopy of plant chromosomes is described. The technique was optimized to use standard squash preparations of mitotic and meiotic chromosomes from root tips of barley, wheat, and rye. After light microscopic observation and documentation, the same object can be investigated with a 100-fold higher resolution using a field emission scanning electron microscope. Tilting of the specimens provides a three-dimensional insight into chromosomal structures at different stages of condensation and decondensation. With this technique it was possible to document for the first time at high resolution structures such as the centromeric region, the spindle apparatus and the spindle fibre attachment region. The smallest unit of the DNA packed that can be resolved is a beads on a string-like structure of the nucleofilament (10–15 nm fibre).by D. Schweizer     

Field emission scanning electron microscopy of plant cells

Summary Two basic specimen preparation protocols that allow field emission scanning electron microscope imaging of intracellular structures in a wide range of plants are described. Both protocols depend on freeze fracturing to reveal areas of interest and selective removal of cytosol. Removal of cytosol was achieved either by macerating fixed tissues in a dilute solution of osmium tetroxide after freeze fracturing or by permeabilizing the membranes in saponin before fixation and subsequent freeze fracturing. Images of a variety of intracellular structures including all the main organelles as well as cytoskeletal components are presented. The permeabilization protocol can be combined with immunogold labelling to identify specific components such as microtubules. High-resolution three-dimensional imaging was combined with immunogold labelling of microtubules and actin cables in cell-free systems. This approach should be especially valuable for the study of dynamic cellular processes (such as cytoplasmic streaming) in live cells when used in conjunction with modern fluorescence microscopical techniques.Abbreviations DMSO dimethylsulfoxide - FESEM field emission scanning electron microscope (-scopy) - MTSB microtubule-stabilizing buffer - PBS phosphate-buffered saline - SEM scanning electron microscope (-scopy) - TEM transmission electron microscope (-scopy)     

High resolution scanning electron microscopy of frog sartorius muscle

A field emission-type scanning electron microscope (SEM) was used to study the three-dimensional ultrastructure of frog sartorius muscles. Various preparative procedures were tested to seeks better specimen preparation for high resolution SEM observation. Procedures should be chosen depending on the information desired. The cell surface and intracellular organization of muscle fibers were best visualized when the tissues were fixed with tannic acid-OsO4 and torn after critical point drying. The basal lamina appeared as a continuous felt-like layer, onto which fine filamentous materials adhered. The true outer surface of the sarcolemma was not seen, whereas the true inner surface was occasionally exposed and exhibited numerous caveolae, membraneous fragments and fine filaments attached to its surface. In freeze-fractured and dried tissues, the cleaved sarcolemma showed numerous apertures of caveolae and T-system tubules. Inside the cell, the myofibrils showed a typical branding pattern of the sarcomere. Thick myofilaments were regularly beaded except for the pseudo-H-zone. Around the myofibrils the sarcoplasmic reticulum and T-system were also clearly observed. The results are discussed with special reference to the usefulness and limitation of the high resolution SEM in studying the ultrastructure of cells and tissues.     

Examination of immobilized fungal cells by phase-contrast and scanning electron microscopy

Conidia of Penicillium urticae were immobilized in kappa-carrageenan beads and then shaken, in a growth-supporting medium to yield an in situ grown population of mycelia. The physical stability of these beads and the degree of mycelial growth inside the beads were significantly affected by the concentrations of kappa-carrageenan and locust bean gum (LBG) in the bead matrix and by the porous or nonporous nature of the interior. Thus 16-h-old porous and nonporous beads, prepared from 1.25% kappa-carrageenan, 0.5% LBG, and conidia, possessed a very dense mycelial mass at the surface. Only the porous beads possessed a moderately dense mycelial mass at the centre. The conidia at the centre of nonporous beads either failed to germinate or formed very small germ tubes. When washed, 36-h-old porous beads were repeatedly (i.e., 48 h) transferred into nitrogen-free medium, the density of mycelia at the centre increased to equal that at the surface after three transfers or 8 days. Mycelia at the surface exhibited signs of physical damage, while those in the centre did not. The addition of 100 micrograms/mL of cycloheximide to these replacement cultures was reflected by the distortion of interior mycelia.     

High resolution scanning electron microscopy of isolated and in situ cytoskeletal elements

Evidence is presented that cytoskeletal structures (actin filaments, intermediate filaments, and microtubules) can be resolved by scanning electron microscopy after osmium impregnation of biological material, using thiocarbohydrazide as a ligand, followed by critical-point drying. These different classes of filaments or tubules can be identified both as purified protein polymers and as structured organelles within cryofractured or detergent-extracted cells.     

Comparative studies of bacterial biofilms on steel surfaces using atomic force microscopy and environmental scanning electron microscopy

Environmental scanning electron microscopy (ESEM) and atomic force microscopy (AFM) were compared as tools for the observation of bacterial biofilms developed on carbon steel and AISI 316 stainless steel surfaces under stagnant conditions. Biofilms were generated in batch cultures of two different isolates of marine sulphate reducing bacteria (SRB) and in cultures consisting of mixed populations of acidophilic bacteria, known as "acid streamers";. Imaging of single SRB cells on mica was also carried out to reveal the surface topography of individual bacterial cells at nanometre resolution. Following the removal of biofilms, the stainless steel surfaces were profiled using AFM to determine the degree of steel deterioration. ESEM and AFM studies of bacterial biofilms in-situ, gave both qualitative and quantitative information on biofilm structure at high resolution. The use of AFM image analysis software allowed estimation of the width and height of bacterial cells, the thickness and width of exopolymeric (EPS) capsule and bacterial flagella, as well as characterisation of the surface roughness of the steel, including measurements of depth and diameter of individual pits. Exposure of stainless steel specimens to acid streamers resulted in a significant increase in the surface roughness of the steel, compared to specimens placed in sterile medium.     

Method of preparing suspended cells for scanning electron microscopy]

To preserve the lifetime morphology of the surface of suspended cells, these must be fixed in suspensions. The subsequent stages of cell preparation for scanning electron microscopy (dehydratation, critical point drying, coating) are considerably facilitated if fixed cells are preliminary attached to some substrate surface. An effective substrate should provide a firm rather than selective attachment of the overwhelming majority of fixed cells; the substrate should be also available for a wide application. The trial of different types of substrates showed a sufficient effectivity of plates made of commercial aluminium foil. In tests with murine embryonal and transformed fibroblasts as well as with human blood leukocytes, in average 90 per cent of cells fixed with glutaraldehyde in suspensions got attached to foil substrate surfaces; the fixed cells both settled from suspension and attached were seen distributed evenly on the substrate surface. The use of aluminium foil substrates made it possible to study the surface topography of some types of suspended cells.     

Microwave processing for scanning electron microscopy

The normal processing of biological samples for Scanning Electron Microscopy, includes treatment with aldehyde (1 to 2 hours), postfixation with Osmium (1 hour), followed by dehydration in a ascending grade of ethanol (30 a 100%), 10 to 15 minutes in each step, and finally drying. This procedure takes at least 8 hours. In this work, samples of mosquitoes (Aedes), protozoa (Tritrichomonas muris), bacteria (Clostridium oceanicum), murine liver, and small intestine were processed in the same manner in a domestic microwave oven for two minutes at 20% of its maximum power. The complete procedure from the initial fixation to dehydration in 100% ethanol was reduced to one hour with good preservation of the ultrastructural details of the specimens.     

Nucleopolyhedrovirus: scanning electron microscopy technique

A simplified methodology was developed to study the geometric form of multiple Bombyx mori Nucleopolyhedrovirus by scanning electron microscopy. The virus belongs to Baculoviridae family and was isolated from the silkworm Bombyx mori (L.) (Lepidoptera: Bombycidae). The polyhedra of Nucleopolyhedrovirus were obtained from the filtrate, inoculum and hemolymph of the silkworm experimentally infected with nuclear polyhedra. This material was placed on stubs, where a copper tape was previously adhered. After dry at room temperature the virus was covered with carbon and gold. Scanning electron microscopy analysis revealed a well defined morphology for the polyhedra of multiple Bombyx mori Nucleopolyhedrovirus, making possible the mathematical study that identified it as a truncated octahedron. The form of the polyhedron can present taxonomic value, once it is specific for each viral lineage.